Modified human U1snRNA molecule, a gene encoding for the modified human U1snRNA molecule, an expression vector including the gene, and the use thereof in gene therapy of familial dysautonomia and spinal muscular atrophy

ABSTRACT

The invention provides a modified human U1snRNA molecule, capable of correcting the skipping of an exon caused by a mutation localized in the sequence comprised between 50 base pairs upstream and 20 base pairs downstream of an exon, wherein a portion of a single-stranded nucleotide sequence of the 5′ region of the wild-type human U1snRNA is replaced by a single-stranded binding nucleotide sequence, wherein the binding nucleotide sequence is selected from the group consisting of: uggcgcuua, aauggcgcu, aguacaauggcgc (SEQ ID NO: 87), gcaaacaguacaau (SEQ ID NO: 88), ucgcaaacaguaca (SEQ ID NO: 89), gcaaacagu, cuagucgcaaac (SEQ ID NO: 90), uacaaaaguaagauuca (SEQ ID NO: 83), aaaccauaaaguuuuacaa (SEQ ID NO: 84) and caaaccauaaaguuuua (SEQ ID NO: 96).

FIELD OF THE INVENTION

The present invention concerns modified human snRNA molecules (hereinafter designated as Exon Specific U1—ExSpeU1), which are suitable to be used in gene therapy methods. In particular, the invention relates to snRNA molecules capable of correcting aberrant splicing processes caused by genetic mutations and related to human diseases with different case histories, which are often very serious.

BACKGROUND OF THE INVENTION

Many human genetic diseases (about 15%) are caused by genetic mutations that, by interfering with the correct messenger RNA intracellular maturation, compromise the accurate subsequent protein biosynthesis and induce synthesis of non-functional proteins. Mostly, the point mutations accountable for splicing defects concern gene sequences that are critical for the recognition of the primary transcript by the machinery appointed for processing the same. The donor and acceptor sites located at the exon-intron boundaries, as well as gene-specific regulatory elements in exons or introns (Cartegni L et al., 2002; Pagani et al., 2004) are among the most significant sequences. As a consequence of these mutations, various molecular events, which most frequently concern the exclusion of one exon from the mature transcript, the so-called exon skipping, may be induced.

It has been known for a long time that molecular changes in the processing of messenger RNA, which involve, for instance, exon skipping, represent the main etiopathogenic mechanism of various human diseases, among which hemophilia B, cystic fibrosis, and spinal muscular atrophy and familial dysautonomia, which share the seriousness of their clinical courses. Different types of mutations can induce exon skipping, and specifically mutations in the donor site (or 5′ splicing site), mutations in the acceptor site (3′ splicing site), or exonic mutations. As examples of different types of mutations that induce exon skipping, following are described three models of human diseases.

The defect in the coagulation factor IX (FIX) accounts for the onset of hemophilia B, a disease accompanied by varying degrees of hemorrhagic manifestations, sometimes very serious and disabling. In some cases, the disease is caused by splicing defects. In particular, the exclusion of exon 5 from mRNA during the splicing process is caused both by mutations at position −2 within the exon 5 donor site of the factor IX gene (F9), and by mutations at positions −8 and −9 within the poly-pyrimidine sequence in the acceptor site.

The limitations of the current hemophilia B therapy, which is mainly based on the frequent infusion of recombinant exogenous FIX or of FIX directly derived from plasma, emphasize the need of developing alternative approaches that are characterized by a greater efficacy and a long-lasting effect.

Cystic fibrosis (CF) is the most frequent lethal congenital hereditary disease in the Caucasian population: one newborn out of 2500-2700 born-alive infants is affected by it.

The pathogenesis of this disease is secondary to an anomaly of a protein designated as CFTR (Cystic Fibrosis Transmembrane Conductance Regulator) localized in the apical membrane of epithelium cells and having the function of regulating the hydroelectrolytic exchanges.

As a consequence of CFTR modification, the transfer of salts through cell membranes is compromised, mainly causing a production of secretions that could be defined as “dehydrated”: a sweat very rich in sodium and chlorine and a dense and viscous mucus that tends to obstruct the ducts, compromising the function of various organs and systems. In the course of several studies, many modifications in the CFTR gene sequence were identified as associated with cystic fibrosis, which induce exon skipping. In particular, skipping of exon 12 is caused both by mutations localized within the splicing donor site of the exon itself, and by exonic mutations.

Spinal muscular atrophy (SMA, OMIM 253300, 253550, and 253400) is a recessive autosomal neuromuscular disease characterized by degeneration of spinal marrow alpha motoneurons, with an estimated prevalence of 1/10,000 born. SMA is associated with clinical syndromes that range from extremely serious, with critical muscle hypotonia and weakness since birth, to milder forms in which the onset occurs later during childhood or adolescence. To date, no treatment for this disease, which generally leads to death at an age that depends on the seriousness of the case history, has yet been identified.

In 95% of cases, the disease is caused by absence of the SMN1 gene. In the human genome, there is a gene homologous to SMN1 called SMN2. However, expression of SMN2 is impaired by a synonymous mutation in the exon which results in an aberrant maturation of the messenger RNA with consequent skipping of exon 7 and inactivation of the gene itself. Approaches designed to increase the number of exon 7-containing SMN2 transcripts would therefore allow to apply a compensation therapy for the absence of the SMN1 gene thanks to the correct expression of SMN2, with considerable implications for a potential effective treatment for SMA.

Familial dysautonomia (“FD”, Rilay-Day syndrome, OMIM 223900) is an autosomal recessive disorder that affects the sensory and autonomic nervous system. FD is a very common disease with a carrier frequency of 1 in 27 in the Ashkenazi Jewish population and of 1 in 18 in Ashkenazi Jews of Polish descent. This neuropathy is characterized by poor development and progressive degeneration of the sensory and autonomic nerves. FD patients show a large number of symptoms due to the loss of neuronal function, including gastrointestinal dysfunction, cardiovascular instability, recurrent pneumonia, decreased sensitivity to pain and temperature, vomiting crisis, and defective lacrimation. To date there is only palliative therapy.

FD is caused by mutations that affect the IKBKAP gene, inducing an aberrant processing of its pre-mRNA. This gene encodes the ikappaB kinase complex associated protein (IKAP), which has a molecular weight of 150 kDa. IKAP is also known as elongator protein 1 (ELP1) that is a component of the human Elongator complex, which is required for an efficient RNA Pol II transcriptional elongation. IKAP has also been associated with other cellular functions in addition to its role in transcription.

As of the present date, there are three known mutations related to FD: an intronic non-coding point mutation (IVS20+6 T>C, c.2204+6T>C, NM_003640.2) and two missense mutations (R696P and P914L). Among these three mutations, it has been found that more than 99% of FD patients are homozygous for the IVS20+6 T>C at the donor splice site of intron 20. This mutation causes exon 20 skipping leading to a frameshift that generates a premature termination codon (PTC) in exon 21 of IKBKAP mRNA. Interestingly, this mutation does not completely abolish the inclusion of exon 20, resulting in a minimal expression of the full-length IKAP protein. However, in neurons, this amount is not sufficient to support a physiological activity, leading to the pathological condition.

During the splicing process, the small nuclear RNAs (snRNAs) play a primary role as essential components of the spliceosome, the cell machinery appointed to mediate the entire mRNA maturation process. In particular, the small U1 RNA (U1snRNA), 164 ribonucleotides in length, is encoded by genes that occur in several copies within the human genome and represents the ribonucleic component of the nuclear particle U1snRNP. The U1snRNA molecules have a stem and loop tridimensional structure and within the 5′ region they include a single-stranded sequence, generally 9 nucleotides in length, capable of binding by complementary base pairing the splicing donor site on the pre-mRNA molecule (Horowitz et al., 1994). FIG. 1 shows a schematic representation of the wild-type U1snRNA structure. The sequence in the 5′ region capable of recognizing the splicing donor site is shown paired with the consensus sequence of the splicing donor site in the primary transcripts of eukaryotic genes. Such a sequence exhibits varying degrees of conservation and is located at the exon/intron junction. The recognition mediated by the U1snRNA 5′ region is critical for defining the exon/intron junctions on the primary transcript and for a correct assembly of the spliceosome complex.

The increasing number of human genetic diseases associated with pre-mRNA splicing defects, and the frequent seriousness of the clinical course of the same, stimulated in the last few years the research for therapeutic molecules aimed at correcting splicing defects at the molecular level.

The use of modified U1snRNA molecules capable of inducing in vitro the correct inclusion of the exon and restoring the correct splicing of coagulation factor VII mRNA in case of mutations located at the 5′ss site is described in Pinotti M et al. 2008 and Pinotti M et al., 2009. The illustrated mechanism is based on the recognition and binding of the modified U1snRNA directly onto the 5′ mutated splicing site. However, this method presents a certain degree of non-specificity of action of the therapeutic snRNA molecule towards the target gene, due to the relative conservation of the 5′ss sites and consequent risk of interfering with the maturation of transcripts generated from other functional wild-type genes. Moreover, it requires the use of a U1snRNA modified for each mutation in the 5′ss.

The present invention demonstrates that modified U1 snRNA molecules complementary to intron sequences downstream of the 5′ splicing site (and herein defined as Exon Specific U1s, ExSpeU1), are capable of restoring, during the splicing process, the exon inclusion which was impaired by different types of mutations. In three different human genetic disease models of therapeutic interest (spinal muscular atrophy, hemophilia, and cystic fibrosis), co-owned U.S. patent application Ser. No. 13/878,355, filed on Apr. 8, 2013, and the work of Fernandez Alanis et al., 2012 demonstrated that a single ExSpeU1 or a group of ExSpeU1s are able to induce the inclusion of the corresponding exon for each disease model. In the work of Dal Mas et al., 2015, it was also shown the effect of the use of three specific ExSpeU1s (sm2, sm17 and sm21) in cellular and animal models of spinal muscular atrophy. In U.S. Ser. No. 13/878,355, it was shown that a single ExSpeU1 or a group of ExSpeU1s correct the exon skipping caused by mutations in the donor site, mutations in the poly-pyrimidine tract of the acceptor site, and mutations in regulatory exon sequences. The correction effectiveness obtained with the ExSpeU1s is the same as that described in the prior art, but it would guarantee a greater selectivity of action on the target gene transcript of therapeutic interest. The ExSpeU1 approach allows use of a single modified U1-snRNA for correcting a panel of different genetic mutations that cause exon skipping. Accordingly, there remains a need in the art for a solution for familial dysautonomia that is caused by exon skipping.

SUMMARY OF THE INVENTION

These and other objects are achieved by a modified human U1snRNA molecule as defined in claim 1. The modified human U1snRNA molecule is characterized in that a portion of the single-stranded nucleotide sequence in the 5′ region of the wild-type human U1snRNA is replaced by a binding single-stranded nucleotide sequence capable of hybridizing to a target nucleotide sequence on the primary transcript of a target gene of therapeutic interest bearing a mutation which induces aberrant splicing. The target nucleotide sequence of the U1snRNA molecule is located in a region of the pre-mRNA comprised between 2 and 50 base pairs downstream of an exon/intron junction site (5′ss), provided that the target nucleotide sequence does not comprise said exon/intron junction site.

Compared to the prior art, the U1snRNA molecules subject of the invention have the advantage of performing a targeted and selective (exon-specific) action, as they bind target nucleotide sequences on the primary transcript localized within the intron regions flanking the splicing donor site, which exhibit a lower degree of conservation compared to the sequences of the exon/intron junction sites. It is however surprising that, though operating on target sequences that do not include the exon/intron junction site, the U1snRNA molecules of the invention are all the same capable of inducing inclusion of the exon in the presence of different types of mutations, including the exonic ones or those on the acceptor site.

Accordingly, the invention provides a modified human U1snRNA molecule, capable of correcting the skipping of an exon caused by a mutation localized in the sequence comprised between 50 base pairs upstream and 20 base pairs downstream of an exon, wherein a portion of the single-stranded nucleotide sequence of the 5′ region of the wild-type human U1snRNA is replaced by a single-stranded binding nucleotide sequence, wherein the binding nucleotide sequence is selected from the group consisting of: uggcgcuua, aauggcgcu, aguacaauggcgc (SEQ ID NO: 87), gcaaacaguacaau (SEQ ID NO: 88), ucgcaaacaguaca (SEQ ID NO: 89), gcaaacagu, cuagucgcaaac (SEQ ID NO: 90), uacaaaaguaagauuca (SEQ ID NO: 83), aaaccauaaaguuuuacaa (SEQ ID NO: 84) and caaaccauaaaguuuua (SEQ ID NO: 96).

In another embodiment, the invention provides for an isolated gene encoding for a modified human U1snRNA molecule. Preferably, the isolated gene comprises a promoter sequence and a polyadenylation signal sequence. The promoter is preferably the endogenous promoter of the gene encoding for human U1snRNA. The invention also provides for an expression vector that includes the isolated gene. The expression vector is preferably an adeno-associated viral vector.

In a further embodiment, the invention provides for a pharmaceutical composition comprising a modified human U1snRNA molecule, a gene encoding the modified human U1snRNA molecule, and/or an expression vector encoding the modified human U1snRNA molecule. In certain embodiments, the pharmaceutical composition preferably further includes a pharmaceutically acceptable carrier.

In a still further embodiment, the invention provides a method of treating a genetic disease, including spinal muscular atrophy and familial dysautonomia, that is caused by or associated with exon skipping, the method comprising administering the inventive modified human U1snRNA molecule, a gene or expression vector encoding the inventive modified human U1snRNA molecule

In yet a further embodiment, the invention provides an in vitro method to restore in a cultured cell the correct splicing of a target gene of therapeutic interest bearing a mutation which induces exon skipping, comprising transfecting the cultured cell with an inventive expression vector, wherein the target gene of therapeutic interest is the SMN gene or the IKBKAP gene.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a schematic representation of the wild-type U1snRNA structure. The sequence in the 5′ region capable of recognizing the splicing donor site (SEQ ID NO: 51) is shown paired with the consensus sequence of the splicing donor site in the primary transcripts of eukaryotic genes.

FIG. 2 illustrates the U1snRNA gene with the promoter elements DSE and PSE, the region encoding for U1snRNA (in the middle), and the 3′ processing box, inserted in a plasmid vector (pGEM). The transcription start site is indicated by an arrow. The sequence between the BglII and BclI restriction sites includes the region encoding for the single stranded U1snRNA tail which has been replaced by oligonucleotides that are specific for generating the modified U1 snRNAs as indicated in Table 1.

FIG. 3 schematically illustrates the middle portion of construct pTB FIX ex5 used for studying splicing.

FIG. 4 illustrates the effects of the expression of minigenes generated in HepG2 eukaryotic cells. The vectors were inserted into the cells by transient transfection and the RNA was analyzed as indicated in the appended method, by using oligonucleotides alfa2-3 and BRA2 as the primers. The illustrated sequences represent the sequences of the acceptor/donor site, with possible mutation(s) as listed by Table 2, hereinbelow. The sequence on the left side of the figure is SEQ ID NO: 52. The sequence on the right side of the figure is SEQ ID NO: 53.

FIG. 5 illustrates localization of the binding sites on the modified U1snRNA employed for the correction of exon 5 splicing defects of the clotting factor IX gene. The sequence of exon 5 is indicated in capital letters, whereas the remaining sequence indicates the intron (SEQ ID NO: 54).

FIG. 6 illustrates different modified U1 snRNAs that were tested on the mutation at position −2C, and their effect on the percentage of exon 5 inclusion.

FIG. 7 illustrates results from Example 3, showing that one single modified U1snRNA, and particularly the one that pairs at position 9 (FIX9), is able to significantly restore splicing in the presence of all the different mutations investigated.

FIG. 8 illustrates a construct wherein a minigene was created in which exon 5 and its flanking intronic sequences have been inserted into the FIX full-length encoding sequence, and cloned into vector pBskFIX. The rectangles indicate the coding sequences, with the ATG start codon and the TAA stop codon, whereas the introns are shown as lines.

FIG. 9 illustrates the results of transfecting the minigene illustrated by FIG. 8 into BHK hamster kidney cells, selected for their ability to synthesize and secrete a functional FIX, demonstrating that the messenger RNA is correctly processed and translated into protein.

FIG. 10 schematically illustrates the pCI-SMN2 minigene.

FIG. 11 illustrates the localization of the modified SMN U1 snRNAs employed for correcting the splicing defect of the SMN2 gene.

-   -   SMN sh25 acuuagaaugaaaacau (this is SEQ ID NO: 83, but written         3′ to 5′),     -   SMN sh2 auucagacg     -   SMN sh40 auuuugaaauaccaaac (this is SEQ ID NO: 96, but written         3′ to 5′)     -   −1G−2G−3A ccucauuca     -   SMN sh37 aacauuuugaaauaccaa (this is nucleotides 2-19 of SEQ ID         NO: 84, but written 3′ to 5′)

The localization of the modified SMN U1 snRNAs are illustrated with respect to the primary transcript of the SMN2 gene, SMB sh37:

-   -   AAGGAguaagucugccagcauuaugaaagugaaucuuacuuuuguaaaacuuuaugguuuguggaaaa         caaa (SEQ ID NO: 104).

FIG. 12 illustrates the effect of modified SMN U1s on SMN2 splicing. The splicing profile of exon 7 of the SMN2 gene (lane 1) and the effect of co-expression of the modified U1 snRNAs (lanes 2-7) are indicated in the upper part of the figure. The two exon 7 inclusion (+) and exclusion (−) isoforms are indicated. In the lower panel the histogram shows the percentage of inclusion of exon 7, and thus, of the correct splicing. The data are the average of three independent experiments.

FIG. 13 schematically illustrates the pTB CFex12 minigene (Pagani et al., 2003). The rectangles represent the middle regions of the a-globin construct, and of the CFTR exon 12, with introns represented as lines. Exon 12 and the flanking intronic regions were cloned into plasmid pTB. The transcription is under the control of the a-globin promoter and SV 40 enhancer. The two possible splicing isoforms are indicated.

FIG. 14 schematically illustrates the localization of the ExSpeU1 efl 1 that was used for correcting the splicing defects of exon 12 of the CFTR gene (SEQ ID NO: 55).

FIG. 15 illustrates the effect of ExSPeU1 cfl 1 on the aberrant splicing induced by different types of mutations localized in the 5′ss and in the exon. ExSPeU1 cfl 1 induces a significant increase in the percentage of inclusion of exon 12 in all the mutants analyzed.

FIG. 16 schematically illustrates the pTB IKAP minigene including the genomic region of IKBKAP gene spanning intron 18 to intron 22. The rectangles represent the middle regions of the a-globin construct, and of the IKBKAP exons, with introns represented as lines. The IKBKAP genomic region was cloned into plasmid pTB. The IVS20+6T>C mutation is indicated. The transcription is under the control of the a-globin promoter and SV 40 enhancer. The normal and aberrant splicing patterns are indicated with dotted lines.

FIG. 17 illustrates the IKAP ExSpeU1s binding regions within the IKBKAP intron 20 (SEQ ID NO: 95).

FIG. 18 illustrates the effects of the different IKAP ExSpeU1s on the aberrant splicing induced by the mutation causing familial dysautonomia. In the lower panel, the histograms report the % of exon 20 inclusion.

DETAILED DESCRIPTION OF THE INVENTION

Preferably, the mutations that are corrected by the ExSpeU1s and cause exon skipping are located in the sequence comprised between 3 and 50 base pairs upstream of an intron/exon junction site (3′ splice site), exonic mutations and mutations within the consensus sequence of the splicing donor site.

The IKBKAP gene and the SMN gene are mentioned by way of example, among the genes of therapeutic interest, that is those bearing mutations related to diseases that lend themselves to treatment with the ExSpeU1s of the present invention.

In a preferred embodiment, the modified human U1snRNA molecule of the invention includes a binding nucleotide sequence selected from the group consisting of uggcgcuua, aauggcgcu, aguacaauggcgc (SEQ ID NO: 87), gcaaacaguacaau (SEQ ID NO: 88), ucgcaaacaguaca (SEQ ID NO: 89), gcaaacagu, cuagucgcaaac (SEQ ID NO: 90), uacaaaaguaagauuca (SEQ ID NO: 83), aaaccauaaaguuuuacaa (SEQ ID NO: 84) and caaaccauaaaguuuua (SEQ ID NO: 96).

In a preferred embodiment, the gene comprises a promoter sequence and a polyadenylation signal sequence. The inventors verified that the endogenous promoter of the gene encoding for human U1snRNA is particularly suitable, although other per se known promoters can also be used, which may easily be selected by a person of ordinary skill in the art.

The sequence of the forward strand of the wild-type human U1snRNA encoding gene (designated as SEQ ID NO: 5 in the sequence listing) is reported hereinafter by way of example, wherein the portion of the single-stranded 5′ region which in the modified U1snRNA molecule is replaced by the binding sequence is in bold. The sequences of the unique BglII and BclI restriction sites, used for inserting the binding sequences, are underlined. In addition to the RNA encoding region, which is shown in capital letters, the SEQ ID NO: 5 gene sequence also comprises some regulatory elements required for its expression, such as the promoter and the polyadenylation signal.

(SEQ ID NO: 5) 5′- taaggaccagcttctttgggagagaacagacgcaggggcgggagggaaaa agggagaggcagacgtcacttccccttggcggctctggcagcagattggt cggttgagtggcagaaaggcagacggggactgggcaaggcactgtcggtg acatcacggacagggcgacttctatgtagatgaggcagcgcagaggctga cgtcttcgccacttgctgcttcaccacgaaggagttcccgtgccctggga gcgggttcaggaccgctgatcggaagtgagaatcccagctgtgtgtcagg gctggaaagggctcgggagtgcgcggggcaagtgaccgtgtgtgtaaaga gtgaggcgtatgaggctgtgtcggggcagaggcccaagatctgATACTTA CCTGGCAGGGGAGATACCATGATCACGAAGGTGGTTTTCCCAGGGCGAGG CTTATCCATTGCACTCCGGATGTGCTGACCCCTGCGATTTCCCCAAATGT GGGAAACTCGACTGCATAATTTGTGGTAGTGGGGGACTGCGTTCGCGCTT TCCCCTGactttctggagtttcaaaagtagactgtacgctaa-3′.

Obviously, the above gene sequence is provided solely by way of example. Alternatively, in order to construct the gene encoding for the modified U1snRNAs of the invention, any gene sequence homologous to SEQ ID NO: 5 can be used, that is one able to encode for a U1snRNA capable of effectively mediating the recognition of the splicing donor site.

The preparation method for the different modified U1snRNA molecules subject of the invention, which contain the different binding sequences, is described in detail in the section of the Examples.

Still another object of the invention is an expression vector comprising an isolated gene as defined previously. The mostly preferred expression vector is an adeno-associated viral vector, although other types of expression vectors, which are per se known to a person of ordinary skill in the art, may also be used.

As previously described, the modified human U1snRNA molecule, the gene encoding for such an RNA molecule, and the vector including said gene are suitable to be used for the therapeutic treatment of a genetic disease caused by or associated with an aberrant splicing and characterized by exon skipping. Preferably, the disease is familial dysautonomia or spinal muscular atrophy.

In particular, it is an object of the invention a method of treating familial dysautonomia comprising administering a modified human U1snRNA molecule including a binding nucleotide sequence selected from the group consisting of uggcgcuua, aauggcgcu, aguacaauggcgc (SEQ ID NO: 87), gcaaacaguacaau (SEQ ID NO: 88), ucgcaaacaguaca (SEQ ID NO: 89), gcaaacagu, cuagucgcaaac (SEQ ID NO: 90), the gene encoding for such molecule or the vector including said gene to a patient in need thereof thereby treating the disease.

It is also an object of the invention a method of treating spinal muscular atrophy comprising administering a modified human U1snRNA molecule including a binding nucleotide sequence selected from the group consisting of uacaaaaguaagauuca (SEQ ID NO: 83), aaaccauaaaguuuuacaa (SEQ ID NO: 84) and caaaccauaaaguuuua (SEQ ID NO: 96), the gene encoding for such molecule or the vector including said gene to a patient in need thereof thereby treating the disease.

Said molecules, genes and/or vectors can be administered to a subject in need thereof by conventional methods. For example, intravenous administration may be used but other forms are equally suitable for carrying out the present invention.

Preferably, the molecules, genes and/or vectors of the invention are used in gene therapy, wherein nucleic acid molecules are delivered into patient's cells as a drug to treat a disease. Gene therapy can be performed according to methodologies well known in the art. In particular, suitable viral vectors may be used to deliver the molecules into the cells. Adeno-associated viral vectors are preferred. These are well known vectors for gene therapy.

The person skilled in the art will decide the effective doses and time of administration, depending on the patient's conditions, degree of severity of the disease, response of the patient and any other clinical parameter within the general knowledge of this matter. Reference can be made to Remington's Pharmaceutical Sciences Handbook, last edition.

To that end, the modified U1snRNA molecule, the gene and/or the vector are formulated into a pharmaceutical composition comprising, in addition to the therapeutically active molecules, a pharmaceutically acceptable carrier and/or excipient. For example, formulation coadjuvants, e.g. solubilizing agents, dispersing agents, suspension agents, and emulsifying agents can be used as carriers or excipients. The selection of the carrier and of the optional pharmaceutical excipients is well within the skill of a person of ordinary skill in the art. Average quantities of the active ingredient in the pharmaceutical composition may vary and in particular should be based upon the recommendations and prescription of a qualified physician.

Another aspect of the invention is an in vitro method for restoring, in a cultured cell, the correct splicing of a target gene of therapeutic interest bearing a mutation that induces an aberrant splicing, by transfecting the cultured cell with an expression vector as defined previously.

The modified U1snRNA molecules subject of the invention were generated by using conventional molecular biology methods which are well known to a person of ordinary skill in the art. To evaluate the effects of the U1snRNAs subject of the invention on the correction of the aberrant splicing processes, and for identifying the most efficient ones, the inventors extensively used the minigene method, the application of which has been widely documented in the scientific literature. Such a method comprises cloning a gene portion bearing the mutation that causes the splicing defects into an expression vector and then transfecting the recombinant vector into in vitro cultured cells. The analysis of the transcripts originated from the portion of the gene of interest is carried out by RT-PCR, thus allowing for the identification of mRNA molecules abnormal in length derived from the aberrant splicing processes. The appearance of transcripts of interest normal in length following co-transfection of the modified U1snRNAs with the minigenes, and the sequencing thereof, represents a clear indication of the ability of the U1snRNA molecules to restore correct splicing processes.

However, the analogy between the restoration of the correct messenger RNA processing and the restoration of the final protein levels, which have the actual therapeutic significance, is not obvious.

For this reason, the inventors used the hybrid minigene method which allows for the study of the splicing, but also of the expressed protein. This method was introduced by the inventors to study a splicing mutation in the coagulation FVII (Pinotti et al., 2009). Such a method comprises cloning into an expression vector a portion of a gene containing a few introns in the region bearing the mutation that causes the splicing defect, within the entire coding sequence (“splicing-competent cDNA construct”), and subsequently transfecting the recombinant vector into in vitro cultured cells. The analysis of the transcripts originated from the portion of the gene of interest by RT-PCR, and the measurement of the levels and activity of the synthesized protein allow for the assessment of the restoration of the biological function.

The following examples are provided by way of illustration and not of limitation of the scope of the invention as defined in the appended claims.

Example 1: Generation of the Modified U1 snRNAs

The modified U1 snRNAs were generated by the following procedure: the plasmid containing the sequence of the wild-type U1-snRNA gene, that is the non-modified U1-snRNA, was digested with the BglII and BclI restriction enzymes. The sequence comprised between these two restriction sites was replaced with a double-stranded oligonucleotide comprising the binding sequence. The direct and reverse sequences of each oligonucleotide are described in Table 1 below and the resulting modified U1-snRNAs are named after the employed oligonucleotides.

Furthermore, FIG. 2 shows a schematic representation of the U1 snRNA gene elements. The cloning strategy by which the different modified U1 snRNAs were prepared is indicated. FIG. 2 shows the U1snRNA gene with the promoter elements DSE and PSE, the region encoding for U1 snRNA (in the middle), and the 3′ processing box, inserted in a plasmid vector (pGEM). The transcription start site is indicated by an arrow. The sequence between the BglII and BclI restriction sites includes the region encoding for the single-stranded U1snRNA tail which has been replaced by oligonucleotides that are specific for generating the modified U1 snRNAs indicated in Table 1.

TABLE 1 SEQ ID NO: Oligonucleotides for U1 FIX exon 5 FIX U1ex5 C3T5A6 dir GATCTCattatgacctgGCAGGGGAGATACCAT 6 FIX U1ex5 C3T5A6 rev gatcatggtatctcccctgccaggtcataatga 7 U1FIXex5 SH-7 dir gatctcatatgacctgctgggcaggggagataccat 8 U1FIXex5 SH-7 rev gatcatggtatctcccctgcccagcaggtcatatga 9 U1FIXex5 SH1 dir gatctcatagattatgacgcaggggagataccat 10 U1FIXex5 SH1 rev gatcatggtatctcccctgcgtcataatctatga 11 U1FIXex5 SH7 dir gatctcatcttattcagatgcaggggagataccat 12 U1FIXex5 SH7 rev gatcatggtatctcccctgcatctgaataagatga 13 U1FIXex5 SH9 dir gatctcattcttattcaggcaggggagataccat 14 U1FIXex5 SH9 rev gatcatggtatctcccctgcctgaataagaatga 15 U1FIXex5 SH10 dir gatctcatatcttattcagcaggggagataccat 16 U1FIXex5 SH10 rev gatcatggtatctcccctgctgaataagatatga 17 U1FIXex5 SH13 dir gatctcataaaatcttatgcaggggagataccat 18 U1FIXex5 SH13 rev gatcatggtatctcccctgcataagattttatga 19 U1FIXex5 SH16 dir gatctcatataaaaaatctgcaggggagataccat 20 U1FIXex5 SH16 rev gatcatggtatctcccctgcagattttttatatga 21 U1FIXex5 SH22 dir gatctcatatttctttaaagcaggggagataccat 22 U1FIXex5 SH22 rev gatcatggtatctcccctgctttaaagaaatatga 23 U1FIXex5 SH33 dir gatctcattcagatacagagcaggggagataccat 24 U1FIXex5 SH33 rev gatcatggtatctcccctgctctgtatctgaatga 25 U1FIXex5 SH38 dir gatctcatagtttcagatgcaggggagataccat 26 U1FIXex5 SH38 rev gatcatggtatctcccctgcatctgaaactatga 27 U1FIXex5 SH63 dir gatctcatttatgtaggtgcaggggagataccat 28 U1FIXex5 SH63 rev gatcatggtatctcccctgcacctacataaatga 29 Oligonucleotides for U1 SMN U1ex7SMN-1G-2G-3A rev gat cat ggt atc tcc cct gcg gag taa gtt atg a 30 U1ex7SMN-1G-2G-3A dir gat ctc ata act tac tcc gca ggg gag ata cca t 31 U1ex7SMN sh2 rev gat cat ggt atc tcc cct gct aag tct gct atg a 32 U1ex7SMN sh2 dir gat ctc ata gca gac tta gca ggg gag ata cca t 33 U1ex7SMN sh17 rev gat cat ggt atc tcc cct gct atg aaa gtt atg a 34 U1ex7SMN sh17 dir gat ctc ata act ttc ata gca ggg gag ata cca t 35 U1ex7SMN sh25 dir gatctcATATACAAAAGTAAGATTCAgcaggggagataccat 97 U1ex7SMN sh25 rev gatcatggtatctcccctgcTGAATCTTACTTTTGTATATga 98 U1ex7SMN sh37 dir gatctcATAAACCATAAAGTTTTACAAgcaggggagataccat 99 U1ex7SMN sh37 rev gatcatggtatctcccctgcTTGTAAAACTTTATGGTTTATga 100 U1ex7SMN sh40 dir gatctcATACAAACCATAAAGTTTTAgcaggggagataccat 101 U1ex7SMN sh40 rev gatcatggtatctcccctgcTAAAACTTTATGGTTTGTATga 102 Oligonucleotides for U1 CFTR exon 12 U1-1A 4T dir gatctcatacatacttggcaggggagataccat 36 U1-1A 4T rev gatcatggtatctcccctgccaagtatgtatga 37 U1 G3 T4 dir gatctcatacacacctggcaggggagataccat 38 U1 G3 T4 REV gatcatggtatctcccctgccaggtgtgtatga 39 U1 T4 A5 dir gatctcatatatacctggcaggggagataccat 40 U1 T4 A5 REV gatcatggtatctcccctgccaggtatatatga 41 U1 CF sh+1 dir gatctctcaaagaacatacgcaggggagataccat 42 U1 CF sh+1 REV gatcatggtatctcccctgcgtatgttctttgaga 43 CF12 SH+9 Dir gatctcataggtattcaaagcaggggagataccat 44 CF12 SH+9 Rev gatcatggtatctcccctgctttgaatacctatga 45 CF12 SH+11 Dir gatctcataagtaaggtattcagcaggggagataccat 46 CF12 SH+11 Rev gatcatggtatctcccctgctgaataccttacttatga 47 CF12 SH+33 DIR gatcatggtatctcccctgctcatgctaaaataga 48 CF12 SH+33 REV gatctctattttagcatgagcaggggagataccat 49 Oligonucleotides for U1 IKBKAP U1 IKBKAP sh2 dir gatctcataTGGCGCTTAgcaggggagatac cat 61 U1 IKBKAP sh2 rev gatcatggtatctcccctgcTAAGCGCCAtatga 62 U1 IKBKAP sh4 dir gatctcataAATGGCGCTgcaggggagataccat 63 U1 IKBKAP sh4 rev gatcatggtatctcccctgcAGCGCCATTtatga 64 U1 IKBKAP sh5 dir gatctcataAGTACAATGGCGCgcaggggagataccat 65 U1 IKBKAP sh5 rev gatcatggtatctcccctgcGCGCCATTGTACTtatga 66 U1 IKBKAP sh10L dir gatctcataGCAAACAGTACAATgcaggggagataccat 67 U1 IKBKAP sh10L rev gatcatggtatctcccctgcATTGTACTGTTTGCtatga 68 U1 IKBKAP sh12 dir gatctcataTCGCAAACAGTACAgcaggggagataccat 69 U1 IKBKAP sh12 rev gatcatggtatctcccctgcTGTACTGTTTGCGAtatga 70 U1 IKBKAP sh15 dir gatctcataGCAAACAGTgcaggggagataccat 71 U1 IKBKAP sh15 rev gatcatggtatctcccctgcACTGT TTGCtatga 72 U1 IKBKAP sh19 dir gatctcataCTAGTCGCAAACgcaggggagataccat 73 U1 IKBKAP sh19 rev gatcatggtatctcccctgcGTTTGCGACTAGtatga 74 U1 IKBKAP sh33 dir gatctcataATCACAAGCgcaggggagataccat 75 U1 IKBKAP sh33 rev gatcatggtatctcccctgcGCTTGTGATtatga 76

Example 2: Transfection of the Minigenes into Cultured Cells and Analysis of the Splicing Products

The containing-vectors were inserted into the cells by transient transfection with Lipofectamine (liposomes). Following extraction of total cellular RNA with Trizol, the RNA was analyzed by RT-PCR with specific primers.

The reaction occurs in two steps: the RNA inverse transcription into a cDNA strand by a reverse transcriptase using random primers as templates, and amplification of the obtained cDNA by a DNA polymerase.

The PCR reaction was carried out in a final volume of 25 μl of a mixture containing:

-   -   5 μl of AMV/Tfl 5× buffer suitable for the correct functioning         of both the enzymes mentioned above;     -   1 μl of 10 mM dNTPs mix;     -   50 pmol of forward primer and 50 pmol of reverse primer;     -   2 μl 25 mM MgSO₄;     -   2 μl of cell-extracted RNA;     -   1 μl of AMV-RT (0.1μ/μl), 1 μl of Tfl DNA polymerase;     -   ultra pure H₂O q.s.

The reverse transcription step was performed at 45° C. for 45 min. A step wherein the PCR mix was adjusted to the temperature of 94° C. for 2 min was then carried out, followed by 40 rounds of PCR, and finally by an extension step for 7 sec at 68° C.

The amplification products were separated by electrophoresis in an agarose gel and/or run by capillary electrophoresis.

Example 3: Exonic Mutations Near the Donor Site and Mutations in the Poly-Pyrimidine Sequence Upstream of the Exon 5 Acceptor Site of the Coagulation Factor IX Associated with Hemophilia B

In the factor IX gene (F9), the exonic mutations at position −2 within the donor site, as well as the mutations at positions −8 and −9 within the acceptor site of exon 5, are associated with hemophilia B. It is interesting to note that the mutations at position −2 in the exon are synonymous and do not modify the coding sequence but induce exon skipping and therefore they are classifiable as splicing mutations. The mutations at positions −8 and −9 within the acceptor site also induce skipping of exon 5.

Table 2 shows the mutations under discussion which were identified in patients affected by hemophilia B (Hemophilia B International database). Nucleotides belonging to exon 5 are shown in capital letters, whereas those belonging to the intron are in lower case. Each position, shown at the bottom of the figure, is affected by one or more mutations, the nucleotide change of which is shown in bold.

TABLE 2 Sequence of the acceptor/donor site Nucleotide Positions: Position substitution −12 to −1\ +1 to +6 Acceptor −8 T > G tgct g cttttag\ATG site (SEQ ID NO: 56) −9 T > G tgc g tcttttag\ATG (SEQ ID NO: 57) Donor −2 A > C CCG\gtcata site −2 A > G CGG\gtcata −2 A > T CTG\gtcata

A vector for the expression of a minigene construct designated as pTB NdeI FIX was constructed to study the splicing of normal and mutated FIX. To do this, a portion of genomic DNA 308 bp upstream of exon 5 and 283 bp downstream of the region affected by the mutations was inserted into a vector widely used to study in vitro splicing, plasmid pTBNdeI (Pagani et al., 2000; Pagani et al 2002; Pagani et al., 2003).

In FIG. 3, the middle portion of construct pTB FIX ex5 used for studying splicing is represented schematically. The rectangles represent the middle regions of the construct of α globin and of FIX exon 5, with the introns represented as lines. Exon 5 and the flanking intronic regions (IVS4 and IVSS) were cloned into plasmid pTB. The transcription is under the control of the α globin promoter and of the SV40 enhancer. The two possible splicing isoforms are indicated.

After inserting the mutations, the inventors have then demonstrated the causative effect thereof by the expression of minigenes generated in HepG2 eukaryotic cells, an ideal cell model for studying proteins of hepatic origin, such as FIX. In particular, the vectors were inserted into the cells by transient transfection and the RNA was analyzed as indicated in the appended method, by using oligonucleotides alfa2-3 and BRA2 as the primers. Specifically, all the mutations induce exon skipping (FIG. 4).

The list of the modified U1-snRNAs created, the target sequences thereof and the localization thereof around the donor site are reported in Table 3.

TABLE 3 Binding sequences of the modified U1-snRNAs for the correction of the splicing defects of exon 5 of the factor IX gene FIX Binding sequence Target sequence Length U1 snRNAs (5′ -> 3′) (5′ → 3′) (bp) C3T5A6 uaugaccug caggtcata 9 FIX-7 ugaccugcugg ccagcaggtca 11 (SEQ ID NO: 50) (SEQ ID NO: 77) FIX1 agauuaugac gtcataatct 10 (SEQ ID NO: 1) (SEQ ID NO: 78) FIX7 ucuuauucaga tctgaataaga 11 (SEQ ID NO: 2) (SEQ ID NO: 79) FIX9 ucuuauuca tgaataaga 9 FIX10 aucuuauuc gaataagat 9 FIX13 aaaaucuua taagatttt 9 FIX16 uaaaaaauc gatttttta 9 FIX22 uuucuuuaa ttaaagaaa 9 FIX33 auucagauacaga tctgtatctgaat 13 (SEQ ID NO: 58) (SEQ ID NO: 80) FIX38 auaguuucagau atctgaaactat 12 (SEQ ID NO: 59) (SEQ ID NO: 81) FIX63 auuuauguaggu acctacataaat 12 (SEQ ID NO: 60) (SEQ ID NO: 82)

The localization of the binding sites on the modified U1 snRNAs employed for the correction of exon 5 splicing defects of the clotting factor IX gene is shown in FIG. 5. The sequence of exon 5 is indicated in capital letters, whereas the remaining sequence indicates the intron.

The different modified U1 snRNAs were tested on the mutation at position −2C, and their effect on the percentage of exon 5 inclusion is shown in FIG. 6. As can be observed, many modified U1 snRNAs are able to significantly increase the percentage of exon 5 inclusion, thereby compensating for the effects of the mutation at position −2C. This indicates that the binding of U1 snRNA to the donor site or nearby (ExSpeU1) favors the definition of exon 5. The efficiency depends on the position, and the U1-FIX1, FIX9, FIX10 show a higher activity. The efficiency decreases with increasing distance from the 5′ss splicing site. It is important to note that the U1 snRNA complementarity to non-conserved intronic sequences flanking the splicing site is important for increasing the specificity thereof. Moreover, it must be pointed out that even small increases in FIX (>2% of normal) would result in a significant improvement of patients' hemorrhagic tendency. For this reason, even the less efficient ExSpeU1 molecules may have a therapeutic significance in hemophilia B, as well as in other clotting defects. With the modified U1snRNA molecules analogous effects were achieved with the other mutations within the donor site (−2A>G, −2A>T) and the acceptor site (−8T>G, −9T>G).

Particularly noteworthy is the demonstration that one single modified U1snRNA, and particularly the one that pairs at position 9 (FIX9), is able to significantly restore splicing in the presence of all the different mutations investigated.

The data related to this finding, never reported till now, are shown in FIG. 7.

The effectiveness of any therapeutic approach is testified by the ability thereof to induce protein synthesis, the levels of which are decreased under the pathological conditions.

To verify if the correction observed at the messenger RNA level results in an increased synthesis and function of secreted FIX, a minigene was created in which exon 5 and its flanking intronic sequences have been inserted into the FIX full-length encoding sequence. FIG. 8 schematically reports the construct generated for this study and cloned into vector pBskFIX. The rectangles indicate the coding sequences, with the ATG start codon and the TAA stop codon, whereas the introns are reported as lines.

Transfection of this minigene into BHK hamster kidney cells, selected for their ability to synthesize and secrete a functional FIX, demonstrated that the messenger RNA is correctly processed and translated into protein (FIG. 9). In fact, considerable amounts of functional protein are measured in the culture medium. By contrast, mutations in the donor site (−2A>G, −2A>T) or in the acceptor site (−8T>G, −9T>G) cause exclusion of exon 5 and synthesis of a truncated protein variant not functional in a normal clotting assay. By Western blotting (upper panel), the mutation was actually proven to cause synthesis of a FIX variant having a lower molecular weight, due to the absence of exon 5 in the coding sequence. No appreciable clotting activity corresponds to this form (lower panel). Expression of the intronic ExSpeU1 fix9 is able to restore splicing and increase the levels of functional secreted FIX up to levels that, if reached in patients, would be largely above the therapeutic threshold. These results confirm the effectiveness of the ExSpeU1 approach.

Example 4: Spinal Muscular Atrophy

Vectors expressing the SMN1 (pCI-SMN1) and SMN2 (pCI-SMN2) minigenes were used for the study (Hua et al., 2007). Such minigenes are widely used to validate the effect of therapeutic molecules capable of correcting the splicing defect in the SMN2 gene (Hua et al., 2007; Hua et al., 2008).

The two minigenes are composed of 111 nucleotides of exon 6, 200 nucleotides of intron 6, the 54 nucleotides of exon 7, the 444 nucleotides of intron 7, and the first 75 nucleotides of exon 8, under the control of the CMV promoter. The two minigenes differ for the presence of one nucleotide substitution at position 6 in exon 7. In pCI-SMN1 there is a C, whereas in pCI-SMN2 there is a T. Such a synonymous substitution induces a splicing defect in pCI-SMN2 with skipping of exon 7 in the mature transcript. The pCI-SMN2 minigene is schematically represented in FIG. 10. The synonymous variant at position +6T in the exon, which induces exon skipping, is indicated.

Many experimental evidences have demonstrated that the correction of the splicing in the SMN2 gene represents an effective therapeutic strategy in SMA (Hua et al., 2007; Hua et al., 2008; Lorson et al., 2010). Table 5 shows a list of the generated modified U1-snRNAs, the target sequences thereof, and their localization around the donor site. The different modified U1-snRNAs and their effect on the percentage of exon 7 inclusion were tested in the SMN2 minigene.

TABLE 5 Recognition sequences (U1-SR) in the gene for the modified U1-snRNAs for the correction of the splicing defect of exon 7 in the SMN2 gene SMN Binding sequence Target sequence Length U1-snRNAs (5′ → 3′) (5′ → 3′) (bp) -1G-2G-3A acuuacucc ggagtaagt 9 SMN_SH 2 gcagacuua taagtctgc 9 SMN_SH 17 acuuucaua tatgaaagt 9 SMN_SH 25 uacaaaaguaagauuca tgaatcttacttttgta 17 (SEQ ID NO: 83) (SEQ ID NO: 85) SMN_SH 37 aaaccauaaaguuuuacaa ttgtaaaactttatggttt 19 (SEQ ID NO: 84) (SEQ ID NO: 86) SMN_SH 40 caaaccauaaaguuuua taaaactttatggtttg 17 (SEQ ID NO: 96) (SEQ ID NO: 103)

FIG. 11 shows the localization of the modified SMN U1 snRNAs employed for correcting the splicing defect of the SMN2 gene.

The minigenes were inserted into HeLa cells by transient transfection with Lipofectamine (liposomes). The RNA was analyzed by RT-PCR as indicated in Example 2. The RNA extracted from the cells was then subjected to RT-PCR with primers pCIFwdB and E8-75 R to assess the splicing products.

As can be observed in FIG. 12, transfection of the pCI SMN2 plasmid into cultured cells mainly shows skipping of exon 7 (lane 1). Co-transfection of the U1ex7SMN −1G−2G−3A (well 2), U1ex7SMN sh2 (well 3), U1ex7SMN sh17 (well 4), U1ex7SMN sh25 (well 5), U1ex7SMN sh37 (well 6) and U1ex7SMN sh40 (well 7) plasmids induces a significant increase in the percentage of inclusion of exon 7.

In particular, FIG. 12 shows the effect of the modified SMN U1s on SMN2 splicing. The splicing profile of exon 7 of the SMN2 gene (well 1) and the effect of co-expression of the modified U1 snRNAs (wells 2-7) are indicated in the upper part of the figure. The two exon 7 inclusion (+) and exclusion (−) isoforms are indicated. In the lower panel the histogram shows the percentage of inclusion of exon 7, and thus, of the correct splicing. The data are the average of three independent experiments.

Example 5: Mutations in the Exon and CFTR Exon 12 Donor Site Associated with Cystic Fibrosis

Cystic fibrosis is caused by mutations in the CFTR gene. Mutations localized in exon 12 splicing site, associated with serious disease forms, which induce aberrant exon skipping are indicated in Table 6. A few mutations localized in exon 12 induce exon skipping (Pagani et al., 2003). Exonic mutations that induce exclusion of exon 12 are indicated in Table 7.

TABLE 6 List of mutations in exon 12 donor site of the CFTR gene. The mutations are shown in bold Sequence of CF exon 12 donor site Nucleotide Positions: −3 −2 −1\ Position substitution +1+2+3+4+5+6 −1 G > A AAA\gtatgt −1 G > T AAT\gtatgt +3 A > G AAG\gtgtgt +3 A > C AAG\gtcgt +5 T > A AAG\gtatat

TABLE 7 Nucleotide Amino acid Position substitution substitution in the exon G > A A566T +17 C > T Y577Y +52

Table 8 shows the recognition sequence in the U1-snRNA gene modified for the correction of the splicing defects in exon 12 of the CFTR gene, which was selected from a larger panel of modified U1 snRNAs.

TABLE 8 CFTR U1- Binding Sequence Target Sequence Length snRNAs (5′ → 3′) (5′ → 3′) (bp) cf11 AUAAGUAAGGUAUUCA TGAATACCTTACTTAT 16 (SEQ ID NO: 4) (SEQ ID NO: 3)

The pTB CFex12 minigene employed is schematically represented in FIG. 13 (Pagani et al., 2003). The rectangles represent the middle regions of the α-globin construct, and of the CFTR exon 12, with introns represented as lines. Exon 12 and the flanking intronic regions were cloned into plasmid pTB. The transcription is under the control of the α-globin promoter and SV40 enhancer. The two possible splicing isoforms are indicated.

FIG. 14 shows the localization of the ExSpeU1 cfl 1 that was used for correcting the splicing defects of exon 12 of the CFTR gene.

The RNA was analyzed by RT-PCR as indicated in Example 2: transfection of the minigenes into cultured cells and analysis of the splicing products, by using alfa2-3 and BRA2 as the primers and the minigene.

FIG. 15 shows the effect of ExSPeU1 cfl 1 on the aberrant splicing induced by different types of mutations localized in the 5′ss and in the exon. ExSPeU1 cfl 1 induces a significant increase in the percentage of inclusion of exon 12 in all the mutants analyzed.

The splicing profile of the different variants (odd wells) and the effect of co-expression of ExSPeU1 cfl 1 (even wells) are indicated in the upper part of FIG. 15. The two exon 12 inclusion (+) and exclusion (−) isoforms are indicated. In the lower panel the histogram shows the percentage of inclusion of exon 12, and thus, of the correct splicing. The data are the average of 3 independent experiments.

The cells were transfected with 0.5 μg of vectors expressing each specific variant. The splicing profile was assessed by RT-PCR with primers ALPHA2,3 and BRA2. The amplified fragments were separated on a 2% agarose gel. The identity of the transcripts including (+) or excluding (−) exon 12 is indicated on the right-hand side of the gel and has been validated by sequencing.

Example 6: Mutation in the IKBKAP Exon 20 Donor Splice Site Associated with Familial Dysautonomia

The most frequent mutation associated with Familial Dysautonomia is the intronic point substitution IVS20+6 T>C, which affects the donor splice site of the IKBKAP exon 20 (Anderson et al. 2001; Slaugenhaupt 2001). This mutation reduces the affinity of the endogenous U1 snRNA, promoting the skipping of exon 20 (Carmel et al. 2004). The hybrid minigene system used to study the aberrant processing of IKBKAP pre-mRNA is the above described pTB-NdeI plasmid (FIG. 16). The expression cassette cloned in this vector has been the genomic region of the IKBKAP gene spanning intron 18 to intron 22 (pTB IKAP wt) (FIG. 16). The intronic point mutation IVS20+6T>C was subsequently inserted by site-directed mutagenesis to create the pTB IKAP+6T>C vector. The rectangles represent the middle regions of the α-globin construct, and of the IKBKAP exons, with introns represented as lines. The transcription is under the control of the α-globin promoter and SV40 enhancer. The normal and aberrant (exon-skipping) splicing pathways are indicated by dotted lines.

Table 9 shows the IKAP ExSpeU1s binding regions within the IKBKAP intron 20, which are schematically represented in FIG. 17.

TABLE 9 IKBKAP Binding Sequence Target Sequence Length U1-snRNAs (5′ → 3′) (5′ → 3′) (bp) IK2 uggcgcuua taagcgcca 9 IK4 aauggcgcu agcgccatt 9 IK5 aguacaauggcgc gcgccattgtact 13 (SEQ ID NO: 87) (SEQ ID NO: 91) IK10L gcaaacaguacaau attgtactgtttgc 14 (SEQ ID NO: 88) (SEQ ID NO: 92) IK12 ucgcaaacaguaca tgtactgtttgcga 14 (SEQ ID NO: 89) (SEQ ID NO: 93) IK15 gcaaacagu actgtttgc 9 IK19 cuagucgcaaac gtttgcgactag 12 (SEQ ID NO: 90) (SEQ ID NO: 94)

FIG. 18 shows the effects of the different ExSpeU1s on the aberrant splicing induced by the mutation causing familial dysautonomia. The mutation promotes exon 20 skipping, as indicated by the intensity of the lower band (lane 2), which is not appreciable in the wild-type context (lane 1).

The splicing correction is appreciable from lane 3 to lane 9 in which the mutant minigene (+6 T/C) has been co-expressed together with the different IKBKAP ExSpeU1 variants. All the ExSpeU1s efficiently promoted the inclusion of exon 20.

Human neuronal SH-SY5Y cells were transfected with 0.5 μg of vectors expressing the wild-type and mutated IKBKAP minigenes. The splicing profile was assessed by RT-PCR with primer ALPHA2,3 and a reverse primer in exon 21 (Exon21 R) (FIG. 16). The amplified fragments were separated on a 2% agarose gel. The identity of the transcripts including or excluding exon 20 (see schematic representation on the right) has been validated by sequencing. In the lower panel of FIG. 18 the histograms report the % of exon 20 inclusion and the results are expressed as mean±standard deviation in at least three independent experiments.

INCORPORATION BY REFERENCE

Numerous references, and other documents, are cited throughout the application, the contents of which are hereby incorporated by reference herein, in their entireties.

REFERENCES

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What is claimed is:
 1. A modified human U1snRNA molecule, capable of correcting the skipping of an exon caused by a mutation localized in the sequence comprised between 50 base pairs upstream and 20 base pairs downstream of an exon, wherein a portion of a single-stranded nucleotide sequence of the 5′ region of the wild-type human U1snRNA is replaced by a single-stranded nucleotide binding sequence, wherein the nucleotide binding sequence is selected from the group consisting of: uggcgcuua, aauggcgcu, aguacaauggcgc (SEQ ID NO: 87), gcaaacaguacaau (SEQ ID NO: 88), ucgcaaacaguaca (SEQ ID NO: 89), gcaaacagu, cuagucgcaaac (SEQ ID NO: 90), uacaaaaguaagauuca (SEQ ID NO: 83), aaaccauaaaguuuuacaa (SEQ ID NO: 84) and caaaccauaaaguuuua (SEQ ID NO: 96).
 2. An isolated gene encoding for a modified human U1snRNA molecule according to claim
 1. 3. The isolated gene according to claim 2, comprising a promoter sequence and a polyadenylation signal sequence.
 4. The isolated gene according to claim 3, wherein the promoter is the endogenous promoter of the gene encoding for human U1 snRNA.
 5. An expression vector comprising an isolated gene according to claim
 2. 6. The expression vector according to claim 5, which is an adeno-associated viral vector.
 7. A pharmaceutical composition comprising a modified human U1snRNA molecule according to claim 1, and a pharmaceutically acceptable carrier.
 8. A pharmaceutical composition comprising an isolated gene according to claim 2, and a pharmaceutically acceptable carrier.
 9. A pharmaceutical composition comprising an expression vector according to claim 5, and a pharmaceutically acceptable carrier.
 10. A method of treating familial dysautonomia caused by, or associated with, exon skipping, the method comprising administering the modified human U1snRNA molecule according to claim 1, to a patient in need thereof, thereby treating familial dysautonomia caused by, or associated with, exon skipping.
 11. A method of treating familial dysautonomia caused by, or associated with, exon skipping, the method comprising administering the isolated gene according to claim 2, to a patient in need thereof, thereby treating familial dysautonomia caused by, or associated with, exon skipping.
 12. A method of treating familial dysautonomia caused by, or associated with, exon skipping, the method comprising administering the expression vector according to claim 5, to a patient in need thereof, thereby treating familial dysautonomia caused by, or associated with, exon skipping.
 13. A method of treating spinal muscular atrophy caused by, or associated with, exon skipping, the method comprising administering the modified human U1snRNA molecule according to claim 1, to a patient in need thereof, thereby treating spinal muscular atrophy caused by, or associated with, exon skipping.
 14. A method of treating spinal muscular atrophy caused by, or associated with, exon skipping, comprising administering the isolated gene according to claim 2, to a patient in need thereof, thereby treating spinal muscular atrophy caused by, or associated with, exon skipping.
 15. A method of treating spinal muscular atrophy caused by, or associated with, exon skipping, the method comprising administering the expression vector according to claim 5, to a patient in need thereof, thereby treating spinal muscular atrophy caused by or associated with exon skipping.
 16. An in vitro method to restore in a cultured cell the correct splicing of a target gene of therapeutic interest bearing a mutation which induces exon skipping, comprising transfecting the cultured cell with an expression vector according to claim 5, in order to upregulate a function of and/or the expression of the target gene of therapeutic interest in the cultured cell, wherein the target gene of therapeutic interest is the SMN gene or the IKBKAP gene. 